US5065455A - Optical atmospheric link system - Google Patents

Optical atmospheric link system Download PDF

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Publication number: US5065455A
Authority: US; United States
Prior art keywords: light beam; optical system; receiver; transmitter; light
Prior art date: 1988-05-20
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime

Application number

US07/352,554

Other languages

English (en)

Inventor

Yujiro Ito

Koji Suzuki

Satoshi Kusaka

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Sony Corp

Original Assignee

Sony Corp

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1988-05-20

Filing date

1989-05-16

Publication date

1991-11-12

1989-05-16 Application filed by Sony Corp filed Critical Sony Corp

1989-07-11 Assigned to SONY CORPORATION reassignment SONY CORPORATION ASSIGNMENT OF ASSIGNORS INTEREST. Assignors: ITO, YUJIRO, KUSAKA, SATOSHI, SUZUKI, KOJI

1991-11-12 Application granted granted Critical

1991-11-12 Publication of US5065455A publication Critical patent/US5065455A/en

2009-05-16 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

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Classifications

- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/11—Arrangements specific to free-space transmission, i.e. transmission through air or vacuum
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/11—Arrangements specific to free-space transmission, i.e. transmission through air or vacuum
- H04B10/112—Line-of-sight transmission over an extended range
- H04B10/1123—Bidirectional transmission
- H04B10/1125—Bidirectional transmission using a single common optical path

Definitions

the present invention relates generally to an optical atmospheric link system and, more particularly, to an optical atmospheric link system which can transmit data by using light beam transmitted in a bidirectional fashion.
This kind of optical atmospheric link system transmits data by utilizing light beams transmitted in space.
transmitter-receiver apparatus are installed on the rooftops of buildings which are apart from each other by several kilometers. Then, the azimuth angles of the light beam to be emitted are adjusted so that the light beams emitted from the transmitter-apparatus irradiate the light receiving portions of the receiving apparatus.
the data can be transmitted between the buildings provided with the transmitter-receiver apparatus respectively.
the transmitter-receiver systems need not be connected to each other via a special network line such as an optical fiber and the like. Hence, data can be transmitted easily.
light beams having sharp directivity can be obtained by the simplified arrangement so that as compared with the system utilizing millimetric waves, microwaves or the like, the optical atmospheric link system can transmit data in the highly-scrambled state.
a wall is provided at a receiver side and the position of a light spot formed on this wall is detected.
the position of the light spot formed on the wall of the receiver side has to be repeatedly detected and the azimuth angle of the emitted light beam has to be repeatedly adjusted on the basis of the detected results transmitted to the transmitter side, which also provides a cumbersome work.
a proposal for solving the above-mentioned problems is made, wherein the azimuth angle of the light beam to be emitted is adjusted by a sighting device formed of a telescope provided in the transmitter side.
the azimuth angle of the light beam to be emitted is adjusted such that the light beam may irradiate the light receiving surface of the receiver.
the optical axis of the light beam and optical axis of the sighting device have to be previously adjusted to be coincident to each other with high accuracy, which provides a cumbersome adjustment.
the above-mentioned proposal can only coarsely adjust the azimuth angle of the emitted light beam. Consequently, the position of the light spot has to be repeatedly detected on the receiver side and the azimuth angle of the light beam to be emitted has to be adjusted on the basis of the detected results transmitted to the transmitter.
a light beam be emitted from the receiver side to the transmitter side to effect the transmission of the position error signal.
the above proposal additionally needs a transmitting apparatus for emitting the light beam from the receiver side to the transmitter side, a light modulating apparatus for modulating the light beam by the position error signal, a demodulating apparatus for demodulating the modulated light beam and so on, which complicates the overall arrangement of the optical atmospheric link system.
a light beam irradiating apparatus When the optical axis adjustment is made by constantly effecting a servo operation, then a light beam irradiating apparatus has to be constantly operated on the receiver side to transmit the position error signal therefrom to the transmitter side.
the light beam emitted from the transmitter system must be widened to some extent, which increases the amount of the light beam.
an optical atmospheric link system for transmitting a light beam carrying an information signal between a transmitter means and a receiver means which is located apart from said transmitter means, said transmitter means comprising:
first optical system means for transmitting said light beam from said light source means toward said receiver means
third optical system means for observing said light beam turned by said second optical system means and said receiver means.
an optical atmospheric link system for transmitting a light beam carrying an information signal between a transmitter means and a receiver means which is located apart from said transmitter means, said transmitter means comprising:
first light source means for generating a first light beam
first optical system means for transmitting said first light beam generated from said first light source means
said receiver means comprising:
first detector means for receiving said first light beam transmitted from said transmitter mean through said first optical system means, detecting the relative position of said first light beam received and said receiver means and for generating a position error signal
second light source means for generating a second light beam modulated with said position error signal generated by said first detector means
said transmitter means further comprises:
second detector means for receiving said second light beam transmitted from said receiver means through said second optical system means and demodulating said second light beam to obtain said position error signal
position control means for controlling the position of said transmitter means according to said position error signal obtained by said second detector means so that said light beam is directed toward said receiver means.
FIG. 1 is a perspective view pictorially illustrating an embodiment of a transmitter-receiver apparatus of an optical atmospheric link system according to the present invention
FIG. 2 is a block diagram showing an azimuth adjusting circuit arrangement of the transmitter-receiver apparatus shown in FIG. 1;
FIG. 3 is a perspective view pictorially illustrating a light beam transmitting-receiving apparatus used in the transmitter-receiver apparatus shown in FIG. 2;
FIG. 4 is a diagrammatic view of a section of a transmitting-receiving optical system of the light beam transmitting-receiving apparatus shown in FIG. 3;
FIG. 5 is a schematic diagram of a fine adjustment optical axis azimuth error detecting circuit used in the transmitter-receiver system of the invention.
FIG. 6 is a schematic representation of a target screen of a television camera used in the present invention.
FIG. 7 is a schematic representation of an image of a laser light source formed on the target screen of the television camera and which is used to explain the operation of the present invention
FIG. 8 is a schematic representation of the target screen of the television camera used to explain how to obtain a position error signal
FIG. 9 is a block diagram showing the light beam focus adjustment system of the optical atmospheric link system according to the present invention.
FIGS. 10A, 10B and 10C are respectively waveform diagrams to which reference will be made in explaining the operation of the light beam focus adjustment system shown in FIG. 9;
FIG. 11 is a schematic diagram used to explain how the spot width of a light spot is changed with the position movement of a laser light source relative to a transmitting-receiving common lens;
FIGS. 12A and 12B are schematic diagrams used to explain the relationship between a video signal and a light spot
FIG. 13 is a block diagram of a focus adjusting circuit used in the present invention.
FIG. 14 is a block diagram of the azimuth coarse adjusting circuit used in the present invention.
FIGS. 15A, 15B, 15C, 15D and 15E are respectively waveform diagrams to which reference will be made in explaining the operation of the azimuth adjusting circuit shown in FIG. 14;
FIGS. 16(A1), 16B and 16(C) are schematic diagrams of the relationship between a video signal and a light spot and are useful for explaining the operation of the azimuth adjusting circuit of the invention shown in FIG. 14;
FIGS. 17A, 17B, 17C, 17D and 17E are waveform diagrams used to explain the operation of the azimuth adjusting circuit of the invention shown in FIG. 14;
FIG. 18 is a plan view illustrating another example of light-shielding plate used in a further embodiment of the present invention.
FIG. 19 is a schematic view used to explain how to operate the light-shielding plate shown in FIG. 18;
FIG. 20 is a perspective view of an optical block used in the collimate scope of the present invention.
FIG. 21 is a diagrammatic view showing a main portion or collimate scope portion of yet a further embodiment of an optical atmospheric link system according to the present invention.
FIG. 22 is a perspective view showing another example of an optical block used in the collimate scope of the present invention.
FIG. 23 is a perspective view of a further example of an optical block used in the collimate scope of the present invention.
FIG. 24 is a diagrammatic view showing a main portion or collimate scope portion of still a further embodiment of an optical atmospheric link system according to the present invention.
FIG. 1 A perspective view forming FIG. 1 illustrates a first embodiment of optical atmospheric link system of the invention.
reference numeral 10 generally designates a first transmitter-receiver apparatus.
the first transmitter-receiver apparatus 10 will be hereinunder referred to as a main transmitter-receiver apparatus.
the main transmitter-receiver apparatus 10 is incorporated within a housing 12 and is installed, for example, on the rooftop of a building to transmit a light beam LA10 carrying an information signal to a second transmitter-receiver apparatus and also to receive a light beam LA20 carrying an information signal transmitted from the second transmitter-receiver apparatus.
the second transmitter-receiver apparatus is constructed substantially the same as the first transmitter-receiver apparatus 10, though not shown. This second transmitter-receiver apparatus will be hereinunder referred to as a target transmitter-receiver apparatus.
the housing 12 of the main transmitter-receiver apparatus 10 has an operation panel 2A attached to its front wall.
On the operation panel 2A there are provided switches 14A, 14B, 14C and 14D and buttons 5A and 5B.
the switch 14A is used to change the picture displayed on a screen of a monitor or display apparatus 13, the switch 14B is used to power the main transmitter-receiver apparatus 10, the switches 14C and 14D are used to match the optical axes in the horizontal and vertical directions, and the switch 14E is used to adjust the focus point.
the buttons 5A and 5B are used to adjust the gain so that the optical axes in the horizontal and vertical direction are adjusted by the servo-control operation.
a display portion 6 is provided on the front panel 2A to display the position irradiated with the light beam and the like.
a receiving portion 9 is mounted on the operation panel 2A in order to receive a remote control signal transmitted from a remote commander 8.
the main transmitter-receiver apparatus 10 can be remotely controlled by using the remote commander 8.
a transparent panel cover 1 is attached to the operation panel 2A by screws 11 so as to cover the monitor apparatus 13, the switch 14A to the button 5B and the display portion 6.
the switch 14A to the button 5B can not be operated directly.
the main transmitter-receiver apparatus 10 is installed, it is remotely controlled by the remote commander 8.
the transmitter-receiver apparatus 10 is designed to transmit the light beam LA10 to a target apparatus which is located very far apart from the transmitter apparatus. Accordingly, even if a very slight shock is applied to the main transmitter-receiver apparatus 10, the irradiation position of the optical beam LA10 is fluctuated considerably. There is then a risk that the optical axis of the light beam LA10 will be fluctuated if the user touches the switch 14A to the button 5B on the operation panel 2A upon adjustment.
the switch 14A to the button 5B on the operation panel 2A are not directly operated but they are remotely controlled by the remote commander 8, which proposal can effectively protect the main transmitter-receiver apparatus 10 from being shocked.
the transparent panel cover 1 is attached to the operation panel 2A by the screws 11 to inhibit the user from directly operating the switch 14A to the button 5B, thus protecting the monitor apparatus 13, the switch 14A to the button 5B and the display portion 6 from being damaged by waterdrops, dust, smudges or the like.
FIGS. 2 and 3 show an alignment control circuit arrangement for the main transmitter-receiver apparatus 10.
the main transmitter-receiver apparatus 10 includes an azimuth adjusting circuit 16 which comprises a coarse adjusting circuit 17 and a fine adjusting circuit 18.
the coarse adjusting circuit 17 is adapted to coarsely adjust the optical axis L of the light beam LA10 toward the target transmitter-receiver apparatus.
the fine adjusting circuit 18 is adapted to fine adjust the azimuth of the optical axis, which was coarsely-adjusted by the coarse adjusting circuit 17 with higher accuracy, whereby the optical axis L of the light beam LA10 substantially becomes coincident with that of the light beam LA20 sent from the target transmitter-receiver apparatus, thereby maintaining a satisfactory optical transmission path in practice.
the coarse adjusting circuit 17 supplies X-axis direction and Y-axis direction coarse adjusting output signal S DX and S DY through fixed contacts a of switching circuits 19X and 19Y to X-axis direction and Y-axis direction driving portions 20X and 20Y of a light beam transmitting-receiving apparatus 20, thereby operating the light beam transmitting-receiving apparatus 20 in the coarse adjustment mode.
the fine adjusting circuit 18 supplies X-axis direction and Y-axis direction fine adjusting output signal S MX and S MY through fixed contacts b of the switching circuits 19X and 19Y X-axis and Y-axis direction driving portions 20X and 20Y of the light beam transmitting-receiving apparatus 20, thereby operating the light beam transmitting-receiving apparatus 20 in the fine adjustment mode.
the X-axis direction and Y-axis direction coarse adjusting output signals S DX and S DY are also supplied to an adjustment error detecting circuit 21.
the detecting circuit 21 is of a comparing circuit arrangement, and compares the output signals S DX and S DY with a change-over reference value in level. When the coarse adjusting output signals S DX and S DY are higher in level than the reference value, the detecting circuit 21 supplies switching signals S WX and S WY to the switching circuits 19X and 19Y so that the switching circuits 19X and 19Y connect their movable contacts to the fixed contacts a to cause the light beam transmitting-receiving apparatus 20 to enter the coarse adjusting mode.
the detecting circuit 21 switches the switching circuits 19X and 19Y so that the switching circuits 19X and 19Y connect their movable contacts to the fixed contacts b to cause the light beam transmitting-receiving apparatus 20 to enter the fine adjusting mode.
the detecting circuit 21 adds the absolute values of Y-axis and X-axis direction coarse adjusting output signal S DY and S DX to generate an added signal K, and determines whether the added signal K is larger than a predetermined value Z.
the switching circuit 19X and 19Y are changed by the switching control signals S WY and S WX so that the switching circuits 19Y and 19X connect their movable contacts to the fixed contacts a to selectively select the Y-axis direction coarse adjusting output signal S DY and the X-axis direction coarse adjusting output signal S DX .
the Y-axis direction coarse adjusting output signal S DY and the X-axis direction coarse adjusting output signal S DX are supplied to driving circuits 28 and 36, respectively in the light beam transmitting-receiving apparatus 20 to thereby still keep the coarse adjusting mode.
the detecting circuit 21 supplies the switching control signal S WY and S WX to the switching circuits 19Y and 19X so that the switching circuits 19Y and 19X connect their movable contacts to the fixed contacts b to select the Y-axis direction fine adjusting output signal S MY and the X-axis direction fine adjusting output signal S MX , thereby effecting the control in the fine adjusting mode.
the predetermined value Z is selected so that it permits the light beam LA10 to properly irradiate photo detectors V1X, V2X and H1X, H2X (see FIG. 5) provided on the target transmitter-receiver apparatus.
the added value K of the absolute values of the Y-axis and X-axis coarse adjusting output signals S DY and S DX is larger than the predetermined value Z, this means that the light beam LA10 does not irradiate the range in which the fine adjusting mode is executed.
the added value K of the absolute values of the error signals S DY and S DX falls within a range of the predetermined value Z, this means that the light beam LA10 irradiates the range in which the fine adjusting mode is executed.
the light beam transmitting-receiving apparatus 10 includes a transmitter-receiver optical system 30 shown in a perspective view forming FIG. 3.
a mount 31 fixed to the housing 12 (FIG. 1) and having an U-letter configuration supports an annular supporting member 32 on an axis 34 by supporting members 33 so that the azimuth of the optical axis L of the light beam LA10 emitted from the transmitting-receiving optical system 30 can be adjusted in the Y-axis direction (vertical direction).
the supporting member 32 is provided with a gear 35 which rotates around the axis 34, and the gear 35 is meshed with a gear 37, whereby when the gear 37 is rotated with a motor 26 secured to the mount 31, the optical axis L of the light beam LA10 is rotated in the vertical direction accordingly as shown by an arrow a in FIG. 3.
the motor 26 is driven by the driving circuit 28 in the Y-axis direction driving portion 20Y as shown in FIG. 2.
the supporting member 32 supports a cylindrical lens supporting member 40 by pivot supporting members 41 so that the lens supporting member 40 can rotate around an axis 42.
the azimuth of the optical axis L of the light beam LA10 can be adjusted in the X-axis direction (left and right direction) as shown in FIG. 3.
the lens supporting member 40 is provided with a gear 43 which rotates around the axis 42, and this gear 43 is meshed with a gear 44, whereby when the gear 44 is rotated by a motor 45 fixed to the supporting member 32, the optical axis L of the light beam LA10 can be rotated in the left and right direction as shown by an arrow b in FIG. 3.
the motor 45 appears also in FIG. 2 and is driven by a driving circuit 36 in the X-axis direction driving portion 20X.
the lens supporting member 40 includes, as shown in FIG. 4, a laser light source 50 and a light receiving portion 51 which are located on the optical axis L so as to be movable along the optical axis L by a focus control motor 142.
the laser light source 50 is properly moved to the focus position of a transmitting-receiving lens 52 by the focus control motor 142, and the laser light source 50 then emits the light beam LA10 which travels through the transmitting-receiving lens 52 along the optical axis L.
the light beam LA20 from the target transmitter-receiver apparatus travels along the optical axis L
the light beam LA20 is received through the transmitting-receiving lens 52 by the light receiving portion 51 which was properly moved to the focus position of the transmitting-receiving lens 52 by the focus control motor 142.
a transmitting circuit 53 receives an information signal S P1 to form a transmission output signal S OUT , and the laser light source 50 receives and converts the transmission output signal S OUT to the light beam LA10.
the light receiving portion 51 converts the light beam LA20, transmitted from the communication object transmitting-receiving apparatus (not shown), to a receiving input signal S IN , and supplies it to a receiving circuit 54.
the receiving circuit 54 forms a receiving information signal S P2 from the receiving input signal S IN , and also supplies to the fine adjusting circuit 18 of the azimuth adjusting circuit 16 (see FIG. 2) fine adjusting servo error signals S VH and S VV which are transmitted from the target transmitting-receiving apparatus in the signal form of being superimposed upon the receiving information signal S P2 .
the fine adjusting servo error signals S VH and S VV are formed such that the irradiation position error of the light beam LA10 irradiated o the communication target transmitting-receiving apparatus from the main transmitting-receiving apparatus 10 are detected by the communication target transmitter receiving apparatus and then to transmitted back to the main transmitter-receiver apparatus 10.
the communication target transmitting-receiving apparatus includes a fine adjustment optical axis azimuth error detecting circuit 51X and detects the displaced amount of the optical axis L of the light beam LA10 transmitted from the main transmitting-receiving apparatus 10 by the four photo detectors H1X, H2X and V1X, V2X located around the incident surface of a transmitting-receiving lens 52X.
the photo detectors H1X and H2X are respectively located at the right and left positions of the transmitting-receiving lens 52X, and supply their detected output signals to a subtracting circuit SUB1.
the subtracting circuit SUB1 subtracts the detected output signals of the photo detectors H1X and H2X to generate the fine adjusting horizontal servo error signal S VH which changes its level, when the optical axis L of the light beam LA10 is displaced from the center of the lens 52X in the horizontal direction in response to the displaced amount of the optical axis L.
P(H1) and P(H2) are the amounts of light beams received by the horizontal photo detectors H1X, H2X, and K H is the proportional constant, respectively.
the vertical photo detectors V1X and V2X are respectively located on the upper and lower sides of the transmitting-receiving lens 52X, and supplies their detected output signals to a subtracting circuit SUB2.
the subtracting circuit SUB2 subtracts the detected output signals to generate the fine adjusting vertical servo error signal S VV whose level is changed, when the optical axis L of the light beam LA10 is displaced from the center of the lens 52X in the vertical direction, with the displaced amount of the optical axis L.
P(V1) and P(V2) are the amounts of light beams received by the vertical photo detectors V1X and V2X, and K V is the proportional constant.
the communication target transmitting-receiving apparatus supplies the fine adjusting servo error signals S VH and S VV to a modulating circuit 53X.
the modulating circuit 53X superimposes the servo error signals S VH and S VV upon the information signal S P2 , transmitted from the target transmitter-receiver apparatus to the main transmitting-receiving apparatus 10, and transmits an output signal S OUTX which is used to obtain the light beam LA20.
the main transmitting-receiving apparatus 10 receives the fine adjusting servo error signals S VH and S VV at the receiving circuit 54 thereof and supplies them to the fine adjusting circuit portion 18 of the azimuth adjusting circuit 16.
the azimuth adjusting circuit 16 processes the fine adjusting servo error signals S VH and S VV to generate an optical axis azimuth signal S CM which makes the signal levels of the servo error signals S VH and S VV to zero.
the azimuth adjusting circuit 16 supplies such optical axis azimuth signal S CM to the X-axis direction driving portion 20X and to the Y-axis direction driving portion 20Y as shown and described with reference to FIG.
the light beam LA10 is, as a result, fine adjusted so that the optical axis L thereof may not be displaced from the center of the transmitting-receiving lens 52X of the communication target transmitting-receiving apparatus.
the main transmitter-receiver apparatus 10 can fine adjust, upon normal operation mode, the emitted direction (namely, the optical axis azimuth) of the light beam LA10 to be identical with the azimuth of the target transmitting-receiving apparatus with sufficient accuracy based upon the fine adjusting servo error signals S VH and S VV transmitted from the target transmitting-receiving apparatus.
the main transmitter-receiver apparatus 10 includes a coarse adjustment optical system ADJ (for use with the coarse adjusting circuit of FIG.
the target transmitting-receiving apparatus may receive the light beam LA10 in the transition of the mode from the stop mode to the operation mode such as when the optical atmospheric link system is installed or when it undergoes a maintenance service or inspection.
the coarse adjusting optical system ADJ includes a television camera 55 which is mounted on the housing 12 to be unitary.
the television camera 55 utilizes a telephoto lens 62 to pick up an image of the surroundings of a place in which the target transmitting-receiving apparatus is installed, it can pick up the emitted position of the light beam LA20 transmitted from the target transmitting-receiving apparatus as well as an image of its surroundings.
a collimate scope 56 is located in front of the television camera 55 and the transmitting-receiving lens 52.
An object bundle of light LA14 travels along the direction substantially parallel to the optical axis L of the light beam LA14 and becomes incident on the collimate scope 56 through a window 63 and a shutter 66.
the collimate scope 56 introduces the object bundle of light LA14 incident thereon through a half mirror 59 thereof and the telephoto lens 62 into the television camera 55 as a picked-up image bundle LA13.
the television camera 55 focuses through the telephoto lens 62 the image of the surroundings of the target transmitting-receiving apparatus and a light spot SP20 of the light beam LA20 on XY coordinates of a target screen 55A, thus making it possible to detect the coordinate position of the light spot SP20 (emitted position of the light beam LA20), or X2 and Y2.
the main transmitter-receiver apparatus 10 and the target transmitting-receiving apparatus are designed to positively transmit data with large density by decreasing the spot width of the data transmission light beams LA10 and LA20 as much as possible.
the light beams LA10 and LA20 are emitted with a high intensity compared to the intensity of the light of the surroundings energy density are introduced as the object light bundle LA14 through the telephoto lens 62 in the coarse adjusting optical system ADJ into the television camera 55 so that it can be focused on the target screen 55A as the light spot SP20 representing the position of the target transmitting-receiving apparatus.
the image focused on the target screen 55A is displayed on the monitor 13 provided on the front panel 12A (see FIG. 1) of the housing 12.
the visual field of the telephoto lens 62 is selected so as to cover a facility 13A (for example, building, etc.) on which the target transmitting-receiving apparatus is installed and the image of its surroundings to be picked up.
the operator can therefore read the position of an image 13B of a receiving light beam emitted from the target transmitting-receiving apparatus as coordinate values on the target screen 55A of the television camera 55, as shown in FIG. 1.
a bundle of light forming one portion of the light beam LA10 emitted through the transmitting-receiving lens 52 is turned toward the lateral direction by a half mirror 58 of the collimate scope 56, and is produced as an extracted light beam LA11 used to detect the emitted position of the light beam.
the light beam LA11 passes through light path of the shutter 65, the half mirror 59, a prism 60, the half mirror 59 and the telephoto lens 62 and travels along the direction nearly parallel to the optical axis L of the transmitting-receiving lens 52 through the telephoto lens 62, thereby being introduced into the television camera 55 as a picked-up bundle of light LA13.
the half mirror 59 is located in parallel to the half mirror 58 with high accuracy and causes the extracted light beam LA11 of the half mirror 58 to travel therethrough into the corner cube prism 60.
the corner cube prism 60 is located so that the light beam LA11 becomes incident on its incident surface 60A.
a reflected light beam LA12 having an optical axis parallel to the light beam LA11 is reflected by the corner cube prism 60 and then introduced into the half mirror 59.
the half mirror 59 reflects the reflected light LA12 at substantially 90 degrees so that the reflected light LA13 (namely, the picked-up bundle of light) is introduced into the television camera 55 through the telephoto lens 62.
the half mirrors 58 and 59 are located in parallel to each other with high accuracy, even when the collimate scope 56 is located with an inclination relative to the optical axis L of the light beam LA10 as shown by an arrow e in FIG. 4, the reflected light LA13 parallel to the optical axis L of the light beam LA10 can be obtained.
the reflected light LA11 from the half mirror 58 is returned by the corner cube prism 60, whereby even when the collimate scope 56 is located with a displacement relative to the optical axis L of the light beam LA10 as shown by an arrow f shown in FIG. 4, the reflected light LA13 parallel to the optical axis L of the light beam LA10 can be obtained.
the television camera 55 therefore focuses the picked-up bundle of light LA10 on the target screen 55A as the light spot SP10, thereby detecting the position of the laser light source 50 as coordinate values on the target screen as shown by X1 and Y1 in FIG. 7.
the bundle of light LA12 forming the light spot SP10 is processed by the collimate scope 56 so as to become incident on the television camera 55 as the picked-up bundle of light LA13 substantially parallel to the light beam LA10 as shown in FIG. 4, it is to be understood that the coordinates at which the light spot SP10 is focused on the target screen 55A as shown in FIG. 7 and the coordinates at which the light spot SP20 is focused on the target screen 55A as shown in FIG. 6 equivalently constitute the same coordinate system.
the light spot SP10 can equivalently express the position at which the light beam LA10 irradiates the vertical surface including the emitted point of the light beam LA20, thus making it possible to detect the optical axis azimuth error of the light beam LA10 from coordinate position errors ⁇ x and ⁇ y on the target screen 55A.
the shutters 65 and 66 are each formed of a liquid crystal optical element.
the shutters 65 and 66 are alternately opened and closed by the coarse adjusting circuit 17, (FIG. 2) whereby the television camera 55 can alternately pick up the image of the light beam LA10 and the image of the object bundle of light LA14 transmitted from the target transmitting-receiving apparatus.
a counter circuit 160 receives a vertical synchronizing signal S V derived from the television camera 55 to generate a frequency-divided signal S 2V whose signal level is changed at a cycle twice as long as that of the vertical synchronizing signal S V .
FIG. 10A shows the waveform of the vertical synchronizing signal S V
FIG. 10B shows the waveform of the signal S 2V .
the shutter 66 is driven by the signal S 2V .
the shutter 65 is driven by an inverted signal S 2IV , resulting from inverting the frequency-divided signal S 2V by an inverting amplifier circuit 161.
the shutters 65 and 66 are operated to alternately open and close at every cycle of the vertical synchronizing signal S V .
the television camera 55 can as a result pick up only the target transmission side during the period T1 in which the frequency-divided signal S 2V is at high level.
Operating the picture change-over switch 14A (see FIG. 1), it is possible to display the image of the target transmission side on the monitor screen of the monitor apparatus 13 as shown in FIG. 6.
the light beam LA20 emitted from the target transmission to the main transmitting-receiving apparatus 10 forms the bright light spot SP20 at the position in which the optical atmospheric link system is installed as shown in FIG. 6.
the television camera 55 properly focuses a bundle of light transmitted from substantially an infinite distance on the target screen 55A because the main transmitter-receiver apparatus 10 is located very distant from the target transmission side.
the light spot SP20 provides the smallest spot width when the light beam LA20 is a collimated light.
the light spot SP20 provides a larger spot width.
the television camera 55 can pick up only the laser light source 50 during the period T2 in which the inverted signal S 2IV is high in level, whereby the bright light spot SP10 is displayed on the monitor screen of the monitor display 13 as an image of the laser light source 50 as shown in FIG. 7.
the light spot SP10 when the light beam LA10 is emitted in the form of a parallel light similar to the light spot SP20, or when the laser light source 50 is located at the focus position of the transmitting-receiving lens 52, the light spot SP10 provides the smallest spot width.
the light beam LA10 is transmitted in the form of a diverged or converged light, or when the laser light source 50 is located ahead of or behind the focus point of the transmitting-receiving lens 52, the light spot SP10 increases its spot width in response to its expansion, as shown in FIG. 11.
the focus control motor 142 is driven by a video signal S E derived from the television camera 55 such that the spot width of the light spot SP10 becomes smallest
the light beam LA10 can be adjusted in the form of the parallel light using only the main transmitter-receiver apparatus 10.
the focusing of the light beam LA10 can be adjusted by a simplified arrangement.
the focus adjusting switch 14E When the focus adjusting switch 14E is remotely operated to be ON by the remote control commander 8 (see FIG. 1) by the main transmitter-receiver apparatus 10, it enters the focus adjusting operation mode, whereby the video signal S E (see A1 to AN+5 in FIG. 12) which goes to high level at every timing in which the light spots SP10 and SP20 are scanned, is supplied to a waveform shaping circuit 163 shown in FIG. 9.
the waveform shaping circuit 163 generates a waveform shaping signal S S which goes to logic level [H] at the leading edge of the video signal S E .
An AND circuit 164 receives the above-mentioned waveform shaping signal S S from the waveform shaping circuit 163, and also receives the inverted signal S 2IV goes to high level during the period T2 together with a subcarrier signal S SC (see FIG. 12B), whereby the AND circuit 164 supplies the subcarrier signal S SC to a counter circuit 165 during the scanning period of the light spot SP10.
the counter circuit 165 is reset in response to the inverted signal S 2IV , and detects a wave number Z (a sum formed of wave numbers Z N+1 , Z N+2 , Z N+3 and Z N+4 shown in FIG. 12B) of the subcarrier signal S SC during the scanning period of the light spot SP10.
the spot width of the light spot SP10 can therefore be detected on the basis of the wave number Z of the subcarrier signal S SC .
the spot width of the light spot SP10 can be minimized by driving the focus control motor 142 so that the wave number Z is minimized.
the frequency-divided signal S 2V drives serially-connected latch circuits 166 and 167, and the latch circuit 166 receives the count value of the counter circuit 165, whereby the serially-connected latch circuits 166 and 167 supply the count value D SPN of the counter circuit 165 and a count value D SPN-1 of one cycle before to a subtracting circuit 168 together.
the subtracting circuit 168 when the laser light source 50 advances toward the focus position of the transmitting-receiving lens 52, the subtracting circuit 168 generates a negative count value D SP , while when it moves away from the focus position of the transmitting-receiving lens 52, the subtracting circuit 168 generates a positive count value D SP .
a drive circuit 170 constantly drives the focus control motor 142 to rotate at a very slow speed.
the drive circuit 170 reverses the driving direction of the motor 142.
the drive circuit 170 constantly drives the focus control motor 142 to detect the change of the spot width of the light spot SP10, whereby the position of the laser light source 50 relative to the focus position of the transmitting-receiving lens 52 can be detected on the basis of the above detected result i.e. whether the change is positive or negative.
the focusing position of the light beam LA10 can be adjusted by locating the laser light source 50 at the focus position of the transmitting-receiving common lens 52.
the focus control motor 142 is driven at a very slow speed so that even when the data is transmitted while adjusting the focus of the light beam LA10, an appropriate spot width sufficient in practice can be obtained.
the latch circuits 166 and 167 shown in FIG. 9 constitute first and second register circuits 171 and 172 which latch the count values D SPN and D SPN-1 in response to the frequency-divided signal S 2V
the subtracting circuit 168 shown in FIG. 9 is constituted of a comparing circuit 173 which compares the count values D SPN and D SPN-1 .
the drive circuit 170 shown in FIG. 9 is constituted a motor drive circuit 174 which drives the focus control motor 142 and an inverting circuit 175 which inverts the driving direction of the motor 142 on the basis of the compared result from the comparing circuit 173.
the counter circuits 160 and 165, the waveform shaping circuit 163 and the AND circuit 164 shown in FIG. 9 constitute a light spot detecting circuit which detects the spot width of the light spot SP10, whereas the focus control motor 142, the latch circuits 166, 167, the subtracting circuit 168 and the driving circuit 170 also shown in FIG. 9 constitute control means which adjusts the distance between the laser light source 50 and the transmitting-receiving common lens 52 on the basis of the detected result of the light spot detecting circuit.
the positions of the respective light spots are detected during the periods T1 and T2 as described above so that if the laser light source is provided on the receiving apparatus side, the emitted position of the light beam LA10 and the position of the receiving apparatus can be detected by the transmitting apparatus without confusion. Further, the optical axis of the light beam LA10 is adjusted on the basis of the above-mentioned detected result, whereby the optical axis can be properly matched by the simplified arrangement.
the positions of the light spots SP10 and SP20 could be detected but it could not be determined which of the light spots SP10 and SP20 corresponded to the light spot of the light beam LA10 or the light spot of the receiving apparatus and vice versa. Thus, it would be unclear in which direction the optical axis L of the light beam LA10 should be corrected. This makes it impossible to properly match the optical axis L of the light beam LA10 accordingly.
the shutters 65 and 66 are alternately opened and closed and the light beam LA13 reflected by the collimate scope 56 and the light beam emitted from the receiving apparatus are alternately introduced into the television camera 55, whereby the light spots SP10 and SP20 can positively be identified, and the direction in which the optical axis is matched can be detected.
the azimuth of the light beam LA10 can be adjusted on the basis of the video signal S E .
a waveform shaping signal S S (see FIG. 15A) is supplied from the waveform shaping circuit 163 (FIG. 9) to a counter circuit 176 and to one input of a flip-flop circuit 177, and a vertical synchronizing signal S V (see FIG. 15B) from the camera 55 and the waveform shaping signal S S is supplied, another input of the flip-flop circuit 177 whereby an AND circuit 178 generates a logical sum of an output signal S1 (FIG. 15C) from the flip-flop circuit 177 and a horizontal synchronizing signal S H from the camera 55 (see FIG. 15D).
FIG. 15A a waveform shaping signal S S
FIG. 15C the waveform shaping circuit 163
a vertical synchronizing signal S V (see FIG. 15B) from the camera 55 and the waveform shaping signal S S is supplied, another input of the flip-flop circuit 177 whereby an AND circuit 178 generates a logical sum of an output signal S1 (FIG. 15C) from the flip-flop circuit
the output signal S1 goes to logic level [H] at a time point t1 in which the vertical synchronizing signal S V goes to high level and which goes to low level at a time point t2 in which the waveform shaping signal S S goes to logic level [H].
the counter circuit 176 generates a signal S2 (see FIG. 15E) which is provided by dividing the waveform shaping signal S S by 2.
This signal S2 and the output signal from the AND circuit 178 are supplied through an OR circuit 180 to a counter 179, whereby the vertical distance Y1 or Y2 (in FIG. 6 or 7) between the scanning start portion on the picked-up image to the center position of the light spot SP10 or SP20 is calculated by the number of horizontal lines.
the number of the horizontal lines is a value in which the distance between the starting portion of the raster scanning and the center of the light spot in the video signal S E (from A1 to AN+5 shown in FIG. 16) is expressed by the horizontal scanning line number n+m/2.
a multiplexer 181 under the control of the signal S 2V alternately supplies the count value D Y of the counter 179 to latch circuits 182 and 183 at every vertical cycle period, whereby a subtracting circuit 184 detects a position error ⁇ y (see FIG. 8) of the position at which the light beam LA10 irradiates the transmission object or target.
the drive circuit 28 drives the motor 26 so as to make the subtracted value representing the position error ⁇ y equal to zero, thereby adjusting the irradiated position in the vertical direction.
a flip-flop circuit 186 receives the horizontal synchronizing signal S H at one input (see FIGS. 16B and 17A) and the waveform shaping signal S S (see FIG. 17B) at a reset input, thereby generating an output signal S5.
the output signal S5 goes to logic level [H] at a time point t5 in which the horizontal synchronizing signal S H goes to high level and goes to logic level [L] at a time point t6 in which the waveform shaping signal S S goes to logic level [H].
An AND circuit 187 receives the output signal S5 and the subcarrier signal S SC (see FIGS. 16C and 17D) and supplies its output signal to a counter 188, whereby the period of time in which the waveform shaping signal S S goes to a logic level [H] at the light spot SP10 or SP20 after the horizontal synchronizing signal S H went to high level can be detected by the wave number N of the subcarrier signal S SC .
a comparing circuit 189 opens, when the count value N of the counter 188 is less than a predetermined value, the gate of an AND circuit 191, thereby supplying the output signal of the AND circuit 187 as delayed by a delay circuit 190, through one input of an OR circuit 192 to a counter 193.
the horizontal synchronizing signal S H goes to high level in the next scanning line.
the delayed output signal of the AND circuit 187 is supplied to the counter 193, whereby only when the light spot SP10 or SP20 exists on the scanning line, the subcarrier signal S SC is supplied to the counter circuit 193.
the horizontal distance from the scanning start portion to the light spot SP10 or SP20 on the picked-up image can be detected by the wave number N (see FIG. 16) of the subcarrier signal S SC .
An AND gate 194 receives as separate inputs the output signal S6 of a frequency divider circuit 195 (see FIG. 17E) which results from frequency-dividing the subcarrier signal S SC by 2 and also the waveform shaping signal S S , thereby supplying an output signal expressing the spot width of the light spot SP10 or SP20 to another input of the OR circuit 192 via a delay circuit 196 having a delay time of one horizontal period (1H).
the counter 193 therefore produces an output D X by counting the wave number N of the subcarrier signal S SC and then counting a value M/2 which is half of the value M expressing the spot width of the light spot SP10 or SP20, whereby the horizontal distance Xl or X2 (see FIGS. 6 and 7) between the scanning start portion to the center position of the light spot SP10 or SP20 on the picked-up image can alternately be detected by the wave number N of the subcarrier signal S SC (see FIG. 16).
Latch circuits 197 and 198 sequentially receive the output signal of the counter circuit 193 in synchronism with the horizontal synchronizing signal S H , thereby supply the count values D X of two adjacent scanning lines to a comparing circuit 199.
the comparing circuit 199 generates a latch signal which goes to high level after the count value D X of the two succeeding scanning lines is increased, it is not changed.
This latch signal is supplied through a multiplexer circuit 200 to latch circuits 201 and 201 alternately.
a multiplexer 203 under the control of the signal S 2V alternately supplies the output signal of the counter 193 to the latch circuits 201 and 202, whereby the latch circuits 201 and 202 respectively supply horizontal position data D X1 and D X2 of the light spots SP10 and SP20 to a subtracting circuit 204.
the subtracting circuit 204 detects a horizontal displaced amount between the two light spots SP10 and SP20.
the drive circuit 36 drives the motor 45 on the basis of the detected result from the subtracting circuit 204, thereby adjusting the irradiating position in the horizontal direction.
the drive circuit 36 determines whether the subtracted value indicating the distance ⁇ x is positive or negative, and drives the motor 45 on the basis of the detected result so as to make the subtracted value zero.
the light beam LA10 emitted from the laser light source 50 and modulated by the predetermined data signal is transmitted through the transmitting-receiving common lens 52 to the transmission object.
the optical axis thereof is turned by the collimate scope 56 so as to be in parallel and is then introduced into the television camera 55.
the television camera 55 alternately generates the image of the laser light source 50 and the image of the transmission object in synchronism with the vertical synchronizing signal S V .
the video signal S E from the television camera 55 is supplied to the waveform shaping circuit 163, in which it is converted to the waveform shaping signal S S which goes to logic level [H] at the light spots SP10 and SP20.
This waveform shaping signal S S is supplied through the AND circuit 164 to the counter circuit 165, thus resulting in the spot width of the light spot SP10 being detected.
the detected result is sequentially latched in the latch circuits 166 and 167, and the output signals of the latch circuits 166 and 167 are supplied to the subtracting circuit 168, whereby it is detected whether the laser light source 50 is moved toward or away from the focus position of the transmitting-receiving common lens 52. Then, on the basis of the detected result, the drive circuit 170 reverses the rotating direction of the focus control motor 142, thereby placing the laser light source 50 at the focus position of the transmitting-receiving common lens 52.
the light beam LA10 emitted from the main transmitter-receiver apparatus 10 is collimated.
the light beam LA10 since the light beam LA10 is bent in parallel and then picked up and the spot width of the light spot SP10 on the basis of the resultant video signal is detected, the light beam LA10 can be adjusted to be a parallel light using only the optical atmospheric link system or the main transmitter-receiver apparatus 10.
the light beam can be adjusted to be a parallel light without a communication line extended from the transmission object side to the target transmitting-receiving apparatus side unlike the prior art, which therefore provides a simplified arrangement and an easy focus adjustment of the light beam.
the present invention is not limited to the above-mentioned shutters but can be applied to a wide variety of shutters such as an electrical shutter and a mechanical shutter.
a light-shielding plate 208 having a cut-away portion of a predetermined angle is provided on the light path and is rotated by a motor 209 in synchronism with the vertical synchronizing signal.
the half mirrors 58, 59 and the corner cube prism 60 are used to parallelly bend the light beam LA10 in the foregoing embodiment as described above, the half mirrors 58 and 59 may be replaced with a prism having a configuration of parallelogram configuration. This will be explained with reference to FIG. 20.
an optical block 220 is formed by bonding right angle prisms 224 and 225 and a parallelogram prism 226. Inclined faces 226A and 226B of the parallelogram prism 226 present the parallelism with high accuracy.
an aluminum thin film is deposited on the inclined faces 226A and 226B of the parallelogram prism 226 to cause the inclined faces 226A and 226B to act as half mirrors.
the optical block 220 is located to direct its inclined face 226A toward the transmitting-receiving common lens 52, whereby the light beam LA10 travels straight therethrough and is also reflected thereon at about 90 degrees.
the reflected light LA11 travels through the inclined face 226B to the corner cube prism 60 (see FIG. 4).
the corner cube prism 60 is located so as to oppose its incident face to an emitting face 220A of the reflected light LA11, whereby a reflected light LA12 of the reflected light LA11 is introduced into the optical block 220 via the corner cube prism 60 in parallel to the reflected light LA12.
the reflected light LA12 is reflected, as a result, on the inclined face 226B parallel to the inclined face 226A at substantially 90 degrees and the reflected light LA13 is introduced into the television camera 55.
the image of the laser light source 50 can be observed on the basis of the reflected light LA13 incident on the television camera 55.
the inclined faces 226A and 226B of the parallelogram prism 226 are arranged with parallelism of high accuracy so that even when the collimate scope 56 is displaced from the optical axis of the light beam LA10 as shown by the arrow e in FIG. 4, or when the inclined face 226A of the parallelogram prism 226 is not precisely opposed to the lens 52 at 45 degrees, the television camera 55 can receive the reflected light LA13 parallel to the optical axis of the light beam LA10.
the reflected light LA11 from the inclined face 226A is reflected on the corner cube prism 60 at the 180 degrees as described above so that even when the collimate scope 56 is displaced from the optical axis of the light beam LA10 as shown by the arrow f in FIG. 4, the television camera 55 can receive the reflected light LA13 parallel to the optical axis of the light beam LA10.
the present invention is not limited to the above-mentioned detecting means but can be applied to a wide variety of detecting means in which other reference clock signals are counted to detect or the like.
the present invention can be modified such that the light beam LA10 is collimated by adjusting the lens position.
the present invention is not limited to the above-mentioned embodiments but can be modified such that the light beam LA10 may be adjusted to be emitted with a predetermined width.
FIG. 21 shows only a main portion of this embodiment, namely, its collimate scope portion for simplicity.
reference numeral 320 generally designates a light transmitting apparatus of the optical atmospheric link system of the present embodiment.
a half mirror 321 is located on the optical axis L of the light beam LA10 with an inclination of substantially 45 degrees, and this half mirror 21 and a corner cube prism 315 constitute the collimate scope.
the face of the half mirror 321 is formed with high accuracy, and to reflect the incident light with the light amount of about half thereof.
one portion of the light beam LA10 is passed through the half mirror 321, and a light beam LA16 of the light beam LA10 reflected on the half mirror 321 becomes incident on the corner cube prism 315.
a light beam LA14 from the target transmitting-receiving apparatus (not shown) is incident on the transmitting apparatus 320 along the traveling direction of the light beam LA10 and is reflected by the half mirror 321 so that it travels in the opposite direction of the reflected light beam LA16, thus resulting in the light beam LA14 being introduced into a telescope 305.
the telescope 305 in FIG. 21 may be replaced with the television camera 55 constructed as shown in FIG. 4.
the corner cube prism 315 is formed such that it introduces a reflected light beam LA17 whose optical axis is parallel to the reflected light beam LA16 through the half mirror 321 to the telescope 305.
the telescope 305 can pick up, as a result, the reflected light beam LA17 emitted from the irradiated position of the light beam LA10, whereby an image similar to that provided when the laser light source is located at the irradiated position can be overlapped on the image of the receiving apparatus side and can be viewed, thus making it possible to visually confirm the irradiated position of the light beam on the transmitting apparatus 320 side positively and easily.
the half mirror 321 is located on the optical axis L of the light beam LA14 as described above, the incident light beam traveling in the opposite direction of the light beam LA10 along the optical axis L of the light beam LA10 can be introduced into the telescope 305 as a light beam parallel to the reflected light beam LA17, which provides the state having parallax.
the single half mirror 321 is located on the optical axis of the light beam LA10 only, the overall arrangement of the apparatus can be simplified by that much.
the reflected light beam LA16 reflectd on the half mirror 321 is reflected in the direction parallel to the same by the corner cube prism 315 and is introduced into the telescope 305 from the direction parallel to the incident light beam LA14 traveling in the opposite direction to the light beam LA10 from the emitted direction of the light beam LA10 as described above.
the half mirror 321 is not accurately located with an inclination of 45 degrees, it is possible to receive the reflected light beam LA17 which travels as though it were emitted from the irradiated position of the light beam LA10.
the half mirror 321 and of the corner cube prism 315 are produced with high accuracy of surfaces, the irradiated position of the light beam LA10 can be confirmed with high accuracy.
the face of the half mirror 321 is produced with high accuracy as compared with the corner cube prism 315 so that . if the corner cube prism 315 is produced with high accuracy in the manufacturing-process, then it becomes possible to obtain an adequate detection accuracy.
the high detection accuracy can be provided by increasing the accuracy of the corner cube prism 315 in the manufacturing-process as described above.
the irradiated position of the light beam can be confirmed with high accuracy regardless of when the whole collimate scope is located with an inclination relative to the optical axis L of the light beam LA10 as shown by an arrow c in FIG. 21, of when the collimate scope 305 is twisted with a displacement relative to the optical axis L of the light beam LA10 as shown by an arrow d in FIG. 21 or of when the telescope 305 is located with an inclination.
the collimate scope is comprised of the half mirror 321 and the corner cube prism 315
the present invention is not limited thereto but can be modified such that the half mirror 321 and the corner cube prism 315 may be formed as one optical block to be unitary.
the corner cube prism 315 is bonded to an optical block 335 which is rectangular in cross section and has a half mirror face 335A at its one end to form the optical block.
an optical block 336 which is circular in cross section and has a half mirror face 336A and a flat incident surface 336B formed on its end.
the corner cube prism 315 is bonded to this optical block 336 to form the optical block.
the half mirror 321 is located on the optical axis L of the light beam LA10, the half mirror 321 is not always located on the optical axis L of the light beam LA10 but it may be located within the bundle of the light beam LA10, making it possible to detect the irradiated position of the light beam adequately.
the half mirror 321 has the reflection efficiency of half of the incident light amount
the present invention is not limited thereto but it is possible to employ a half mirror having a high reflection efficiency or a half mirror having a low reflection efficiency, if necessary.
the present invention is not limited to the above embodiment but can be varied as follows. That is, the whole of the light beam LA10 is introduced into the telescope 305 and the collimate scope may be removed after the completion of the adjustment.
FIG. 24 illustrates only its collimate scope portion, which is the main portion of the embodiment, for simplicity.
reference numeral 430 generally designates a transmitting apparatus of the optical atmospheric link system of the present embodiment.
a half mirror 431 is located on the optical axis L of the light beam LA10 with an inclination of about 45 degrees.
the half mirror 431 and the corner cube prism 415 constitute the collimate scope.
the face of the half mirror 431 is formed with high accuracy, and is also arranged to reflect about half of the amount of the incident light, whereby one portion of the light beam LA10 travels through the half mirror 431 and its reflected light beam LA18 from the half mirror 431 becomes incident on a telescope 405.
the optical system of telescope or the like is provided with a lens on its incident surface so that the light amount of the so-called reflected back light beam reflected on the incident surface and which is fed through the half mirror 431 and a lens back to the laser light source can be considerably reduced.
the amount of the reflected back light beam can be reduced in an enough range in practice and the light beam LA10 having less noise as compared with the prior art can be obtained, thus making it possible to transmit data of high quality.
the light beam LA15 incident on the transmitting apparatus 430 from the irradiated direction of the traveling light beam LA10 is reflected by the half mirror 431 in the direction opposite to that of the reflected light LA18 and its reflected light LA19 becomes incident on the corner cube prism 415.
the corner cube prism 415 therefore produces a reflected light beam LA20 which is parallel to the optical axis of the reflected light beam LA19, and the reflected light beam LA20 passes through the half mirror 431 and becomes incident on the telescope 405.
the component of the incident light beam LA15 whose optical axis is parallel to the light beam LA10 is introduced into the telescope 405 parallel to the reflected light beam LA18 of the light beam LA10, thus making it possible to obtain the reflected light beam LA20 emitted as though it were emitted from the irradiated position of the light beam LA10.
the same image as that provided when the laser light source is located at the irradiated position can be overlapped on the image of the receiving apparatus side and can be visually confirmed. This makes it possible to easily and positively confirm the irradiated position of the light beam on the transmitting apparatus 403 side.

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Physics & Mathematics (AREA)
Electromagnetism (AREA)
Engineering & Computer Science (AREA)
Computer Networks & Wireless Communication (AREA)
Signal Processing (AREA)
Optical Communication System (AREA)

US07/352,554 1988-05-20 1989-05-16 Optical atmospheric link system Expired - Lifetime US5065455A (en)

Applications Claiming Priority (2)

Application Number	Priority Date	Filing Date	Title
JP63123543A JP2705104B2 (ja)	1988-05-20	1988-05-20	送信装置
JP63-123543		1988-05-20

Publications (1)

Publication Number	Publication Date
US5065455A true US5065455A (en)	1991-11-12

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ID=14863198

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US07/352,554 Expired - Lifetime US5065455A (en)	1988-05-20	1989-05-16	Optical atmospheric link system

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US (1)	US5065455A (ja)
JP (1)	JP2705104B2 (ja)
KR (1)	KR970004784B1 (ja)
DE (1)	DE3916362C2 (ja)
FR (1)	FR2631759B1 (ja)
GB (1)	GB2218874B (ja)

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JPH021633A (ja)	1990-01-05
GB2218874A (en)	1989-11-22
KR900019416A (ko)	1990-12-24
FR2631759B1 (fr)	1995-02-03
KR970004784B1 (ko)	1997-04-03
JP2705104B2 (ja)	1998-01-26
DE3916362A1 (de)	1989-12-07
FR2631759A1 (fr)	1989-11-24
GB8911305D0 (en)	1989-07-05
DE3916362C2 (de)	1997-07-17
GB2218874B (en)	1992-07-15

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